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钛合金薄板激光和钨极氩弧焊残余应力测试研究 被引量:6

Residual Stress Measurements with the Hole-drilling Technique in the Joints by the Laser and TIG Welding for a Thin Plate of Titanium Alloy
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摘要 采用小孔释放法对钛合金薄板激光焊和钨极氩弧焊(TIG焊)的焊接残余应力进行了测试,并分析了焊接方法、焊接线能量和焊后热处理对残余应力分布规律的影响。研究结果表明:激光焊残余应力分布规律与普通熔焊方法相似,但其分布区域较窄;在热影响区内,激光焊残余拉应力值比TIG焊的约低100MPa;在焊缝及其熔合线附近,激光焊残余应力却比TIG焊的高。对于不同线能量激光焊接,线能量越大,焊缝越宽,热影响区的残余应力也越大。焊后真空热处理能降低残余应力90%。 A hole-drilling technique was used to determine the residual stress in laser beam welding (LBW) and TIG welding joints of titanium alloy thin plate. The effects of different welding technologies, heat input and post-weld heat treatment on residual stress distributions were analyzed. The results show that the distribution of laser welding residual stress is similar to that of traditional fusion welding processes, but the zones of distribution are much narrower. Compared to that of TIG welding in HAZ, the values of laser welding residual stress are lower about 100MPa. For the different heat input of LBW, the heat input is higher, the weld is wider and the residual stress in HAZ is bigger. Post-weld vacuum heat treatment would relieve residual stress about 90%.
作者 何小东 张建勋 巩水利 李继红
机构地区 西安交通大学材料科学与工程学院 北京航空工艺研究所
出处 《材料工程》 EI CAS CSCD 北大核心 2003年第12期7-10,共4页 Journal of Materials Engineering
基金 高能束流加工技术国防科技重点实验室基金资助(51461010203JW0801)
关键词 钛合金薄板 激光焊 TIG焊 应力分布 钨极氩弧焊 小孔释放法 titanium alloy laser beam welding TIG welding weld residual stress hole-drilling technique
分类号 TG404 [金属学及工艺—焊接] TG457.1 [金属学及工艺—焊接]
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  • 1关桥.飞行器薄壳结构焊接变形控制与焊接力学的发展.航空连接技术重点试验室论文选编[M].北京航空工艺研究所,1998..
  • 2[1]Anon. Titanium alloys for aerospace[J] . Advanced Materials & Processes, 1999, 155(3): 39.
  • 3[2]Lineberger, Lane. Titanium aerospace alloys [J] . Advanced Materials & Processes, 1998, 153(5):45.
  • 4[3]The F - 22 Story: Building Affordability [J]. Flight InternationalSupplement, 1997, (4) :9.
  • 5[4]Yoshimitsu okazaki, Yoshimasa Ito. Corrosion resistance and corro sion fatigue strength of new titanium alloys for medical implants without V and Al[J]. J. Materials Science and Engineering A, 1996, 213:138.
  • 6[5]Niinomi, Mitsuo. Recent titanium R&D for biomedical applications inJapan [J] .JOM, 1999, 51(6) :32.
  • 7[6]Kathy Wang. The use of titanium for medical applications in USA[J] .J. Materials Science and Engineering A, 1996, 213 : 134.
  • 8[7]Sherman A M, Sommer C J, Froes F H. Use of titanium in produc tion automobiles: potential and challenges [J]. JOM, 1997, 49 ( 5 ):38.
  • 9[8]Shira, Chet, Froes F H. Titanium golf clubs. TMS Annual Meeting, Sponsored by: TMS Minerals [J]. Metals & Materials Soc (TMS), 1998, Feb. 16 - 19: 331.
  • 10[9]Vandermark, Robert. Opportunities for the titanium industry in bicy cles and wheelchairs[J]. JOM, 1997, 49(6):24.

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材料工程
2003年 第12期

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